JP2009158011A - Information recording device and information recording method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an information recording device capable of suppressing consumption of a battery due to synchronous processing, and to provide an information recording method. <P>SOLUTION: The information recording device is a device for writing data to a disk-shaped recording medium and a cache memory, and includes: a memory section which stores connection information showing a presence or an absence of connection of an external power source; a determination section for determining whether to write data recorded only in the cache memory to the disk-shaped recording medium; and a writing section for writing the data recorded only in the cache memory to the disk-shaped recording medium according to the determination result. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an information recording apparatus and an information recording method for writing data to a disk-shaped recording medium and a cache memory.

In recent years, information recording apparatuses using a hard disk as a disk-shaped recording medium and a semiconductor storage medium as a cache memory have been developed. Here, when there is data stored only in the cache memory, the data safety can be improved by storing this data in the disk-shaped recording medium (data synchronization processing).
In addition, when the power is turned off before writing from the cache memory to the magnetic disk device, a technique for writing to the magnetic disk device after the power is turned on is disclosed. Data can be guaranteed and reliability can be improved (see Patent Document 1).
JP-A-6-348600, claim 4, paragraph number 0056

By the way, mobile devices are becoming more and more mobile devices that use batteries. Since writing to the magnetic disk device requires a relatively large amount of power, when the device is operating on a battery, writing to the magnetic disk device, that is, the synchronization processing being suppressed leads to long-term use of the device. With the technique described in Patent Document 1, the synchronization process cannot be suppressed in correspondence with battery driving.
In view of the above, an object of the present invention is to provide an information recording apparatus and an information recording method capable of suppressing battery consumption due to synchronization processing.

  An information recording apparatus according to an aspect of the present invention is an information recording apparatus that writes data to a disk-shaped recording medium and a cache memory, the storage unit storing connection information indicating whether or not an external power source is connected, and the connection information A determination unit for determining whether or not to write data recorded only in the cache memory to the disk-shaped recording medium, and corresponding to the result of the determination, the data recorded only in the cache memory A writing unit for writing to the disk-shaped recording medium.

  An information recording method according to an aspect of the present invention is an information recording method in an information recording apparatus for writing data to a disk-shaped recording medium and a cache memory, and an access indicating permission or prohibition of access to the disk-shaped recording medium Corresponding to the availability information, the data is recorded only in the cache memory on the basis of the step of writing data into either the disk-shaped recording medium and the cache memory or only the cache memory, and the presence or absence of a predetermined detection. Determining whether to write data to the disk-shaped recording medium; and writing data recorded only in the cache memory to the disk-shaped recording medium in response to the determination result. .

  ADVANTAGE OF THE INVENTION According to this invention, the information recording device and information recording method which can suppress the consumption of the battery by a synchronous process can be provided.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
(First embodiment)
FIG. 1 is a block diagram showing an information recording system 10 according to the first embodiment of the present invention. The information recording system 10 includes a host device 100 and an information recording device 200.

  The information recording apparatus 200 includes a hard disk (HD) 201, flash memory 202, SDRAM 203, main controller 210, power supply 220, power supply controller 231, operation switch 232, status sensor 240, host interface (I / F) 251, disk interface (I / F) 252, flash memory interface (I / F) 253, SDRAM interface (I / F) 254, power supply interface (I / F) 255, sensor interface (I / F) 256, switch interface (I / F) 257 Have

  The host device 100 is a control unit in a device that writes and reads information to and from the information recording device 200, for example, a personal computer. The host device 100 can send a command to the main controller 210 via the host interface 251. The host device 100 can also receive data from the main controller 210 via the host interface 251.

  The host interface 251 can use an interface conforming to the ATA (Advanced Technology Attachment) standard, for example, parallel ATA (PATA), serial ATA (SATA), or CE-ATA. Further, a standard other than the ATA standard, for example, a USB (Universal Serial Bus) standard may be adopted for the connection between the host device 100 and the host interface 251. Further, the host device 100 and the host interface 251 may be connected via a LAN (Local Area Network). If necessary, the host interface 251 can include a protocol conversion unit that converts a protocol between signals of different standards.

  The main controller 210 can exchange data with the HD 201, the flash memory 202, and the SDRAM 203 via the disk interface 252, the flash memory interface 253, and the SDRAM interface 254, respectively.

  The HD 201 has a magnetic disk, a spindle motor, a magnetic head, and an arm. A magnetic disk is a disk-shaped recording medium for recording information. The spindle motor rotates the magnetic disk. The magnetic head writes and reads data on the magnetic disk. The arm holds the magnetic head and moves it over the magnetic disk.

  The flash memory 202 is used as a cache when recording on the HD 201. For this reason, the flash memory 202 includes a cache table in addition to a write area for writing data. In the cache table, cache information (address 1, address 2, and synchronization information) is represented. Address 1 and address 2 are addresses (for example, physical addresses) on the flash memory 202 and the HD 201, respectively. The synchronization information indicates whether or not the data corresponding to the address 1 of the flash memory 202 is actually written on the HD 201 (the presence or absence of synchronization). As will be described later, there is a possibility that data is written only to the flash memory 202 and not written to the HD 201.

The SDRAM 203 is used as a buffer when recording on the HD 201.
An error correction code is added to the data recorded in the HD 201 and the flash memory 202. ECC processing is applied to the recording data to the flash memory and the recording data to the hard disk so that error correction at the time of reproduction is possible.

  When data is written from the host device 100 to the HD 201, the data is written via the flash memory 202 and the SDRAM 203. For example, data is written in the following order. (1) SDRAM 203, HD 201 system path. (2) System path of the flash memory 202 and HD 201. (3) System path of the flash memory 202, SDRAM 203, and HD 201. (4) System path of SDRAM 203, flash memory 202, and HD 201. (5) A system path of the SDRAM 203, the flash memory 202, the SDRAM 203, and the HD 201. In the case of (2) to (5), cache information is added to the cache table (addition of an entry).

  In addition, when data is read from the HD 201 to the host device 100 side, the data is read via the flash memory 202 and the SDRAM 203. For example, data is read in the following order. (1) A system path of the HD 201, SDRAM 203, and host device 100. (2) A system path of the HD 201, the flash memory 202, and the host device 100. (3) A system path of the HD 201, the flash memory 202, the SDRAM 203, and the host device 100. (4) System path of the HD 201, SDRAM 203, flash memory 202, and host device 100. (5) System path of the HD 201, SDRAM 203, flash memory 202, SDRAM 203, and host device 100.

  Although the flash memory 202 is a non-volatile memory, data can be electrically erased and rewritten, that is, data can be rewritten. In the flash memory 202, when the number of times of rewriting increases, the element deteriorates, an error (for example, read disturb or data retention) occurs, and the written content may be corrupted. Therefore, as information for guaranteeing the performance of the flash memory 202, the number of rewrites is defined to be about 100,000, for example.

  The writing area of the flash memory 202 can be divided into a pinned area and an unpinned area.

  The Pinned area is an area formed when a command sent from the host apparatus 100 designates the flash memory 202 as a data write destination. Along with this command (Pinned command), a logical block address (LBA) is designated. When the host apparatus 100 issues a Pinned command and designates the Pinned area as an address (Pinned LBA), data is written in the Pinned area.

  On the other hand, the UnPinned area is an area where the data write destination by the host apparatus 100 is not specified by a command, and the main controller 210 uniquely determines and transfers and stores the data. When the flash memory 202 is used as a cache memory, data is written in the UnPinned area. In this case, the host device 100 does not need to be aware of the address of the cache memory 202, and may specify the address on the HD 201 side.

  As the flash memory 202, a memory conforming to the standard “Non Volatile Cache Command Proposal for ATA8-ACS” can be used.

The power source 220 has a battery that stores and supplies power from an external power source.
The power controller 231 detects connection of an external power source to the power source 220. For example, it recognizes the insertion / extraction of the external power supply terminal to the external power supply connector of the power supply 220. That is, the power supply controller 231 functions as a detection unit that detects connection of an external power supply to the power supply 220.

  The detection result (connection of external power supply) in the power supply controller 231 is notified to the main controller 210 via the power supply interface 255. Control signals and commands can be used for this notification. As a command, either a dedicated command or an unused part (argument part) of an existing command can be used. Further, the detection result may be notified to the main controller 210 using a physical switch instead of the control signal and the command.

  The operation switch 232 is an input unit for inputting information corresponding to detection of connection of an external power source to the power source 220. That is, by operating the operation switch 232, processing corresponding to the processing when the connection of the external power source to the power source 220 is detected (for example, data synchronization between the flash memory 202 and the HD 201) is performed.

  The state sensor 240 is a sensor that detects the state (for example, vibration, acceleration, temperature, atmospheric pressure) of the information recording apparatus 200. This detection result is used to determine whether access to the HD 201 is prohibited or permitted by the access permission determination unit 212. When the state of the information recording apparatus 200 is not suitable for the operation of the HD 201 (for example, when the acceleration is larger than a predetermined value), access to the HD 201 can be prohibited. It is also possible to manually input the quality of the state to the state sensor 240 using an operation switch or the like.

  The main controller 210 includes a command analysis unit 211, an access permission determination unit 212, an access permission storage unit 213, a connection information storage unit 214, an operation information storage unit 215, a synchronization determination unit 216, and a writing / reading unit 217.

  The command analysis unit 211 analyzes a command sent from the host device 100. This command includes a data write instruction, a data read instruction, a data size designation, a data transfer, a memory, and an information read instruction. The command analysis unit 211 functions as a write detection unit that detects a write command from the host device 100.

  Based on the detection result of the state sensor 240, the access permission / non-permission determining unit 212 determines whether access to the HD 201 is prohibited or permitted, and rewrites the contents stored in the access permission / non-permission storage unit 213. The access enable / disable storage unit 213 stores the determination result of the access enable / disable determination unit 212.

The connection information storage unit 214 stores the detection result of the connection of the external power source notified from the power controller 231. The connection information storage unit 214 functions as a storage unit that stores connection information indicating whether or not an external power source is connected.
The operation information storage unit 215 stores the operation result of the operation switch 232. That is, the operation information storage unit 215 functions as a second storage unit that stores access permission information indicating permission or prohibition of access to the disk-shaped recording medium.

  The synchronization determination unit 216 determines whether or not data recorded only in the flash memory 202 is written to the HD 201 (whether or not data is synchronized between the flash memory 202 and the HD 201). The synchronization determination unit 216 functions as a determination unit that determines whether or not to write data recorded only in the cache memory to the disk-shaped recording medium based on the connection information.

  The writing / reading unit 217 writes / reads data to / from the HD 201, the flash memory 202, and the SDRAM 203. The writing / reading unit 217 functions as a writing unit that writes data recorded only in the cache memory to the disk-shaped recording medium. The writing / reading unit 217 also functions as a second writing unit that writes data to either the disk-shaped recording medium and the cache memory or only to the cache memory.

  The writing / reading unit 217 also erases data from the HD 201, the flash memory 202, and the SDRAM 203. That is, the writing / reading unit 217 also functions as a deletion unit that deletes data written on the disk-shaped recording medium from the cache memory.

(Operation of information recording apparatus 200)
Hereinafter, an operation procedure of the information recording apparatus 200 will be described.
FIG. 2 is a flowchart showing an example of an operation procedure of the information recording apparatus 200.
(1) Detection of write command (step S11)
The command analysis unit 211 detects a write command sent from the host device 100. That is, a write command for instructing data writing is sent from the host apparatus 100 to the main controller 210 and detected by the command analysis unit 211.

(2) Confirmation of presence or absence of prohibition of access to HD 201 (step S12)
It is confirmed whether or not access to the HD 201 is prohibited. That is, the determination result stored in the access permission / non-permission storage unit 213 is referred to, and it is confirmed whether this determination result represents prohibition or permission of access to the HD 201.

(3) Writing data to the flash memory 202 (step S13)
When it is confirmed that access to the HD 201 is prohibited, data is not written to the HD 201 and data is written only to the flash memory 202 (or to the SDRAM 203).

(4) Write data to HD 201 and flash memory 202 (step S14)
When it is confirmed that access to the HD 201 is permitted, data is written to the HD 201 and the flash memory 202. Details of this will be described later with reference to FIGS.

  Note that the access target (for example, the data write destination) is not necessarily determined only by the determination result stored in the access enable / disable storage unit 213. For example, at the time of writing in step S14, it is selected whether to write to both the HD 201 and the flash memory 202 or to one. The controller 210 selects the access target so that the response to the host device 100 is quick, the impact resistance is high, and the power consumption is reduced. For example, when the rotation of the magnetic disk in the HD 201 is stopped (waiting for rotation), the flash memory 202 is selected as the write destination. This situation is the same in steps S33 and S47 described later.

  Since the flash memory 202 has no drive system elements, it is generally resistant to shock during access and consumes little current. On the other hand, a magnetic storage device such as the HD 201 generally has a low current consumption and a large current consumption because the magnetic head physically accesses data on a rotated medium (magnetic disk).

  For this reason, by prohibiting access to the HD 201 based on the determination result stored in the access enable / disable storage unit 213, it is possible to increase shock resistance and reduce power consumption while using the HD 201.

  However, if this control is continued and the write operation is continued in a state where access to the HD 201 is prohibited, the amount of data (asynchronous data) that does not exist in the HD 201 and exists only in the flash memory 202 increases. To do. Considering the limitation on the number of rewrites of the flash memory 202 and the like, a state in which there is data only in the flash memory 202 does not necessarily mean that the data is completely stored.

  As described below, in the present embodiment, data existing only in the flash memory 202 is written to the HD 201 in accordance with whether or not an external power supply is connected (data synchronization (data flash)). As a result, data is more reliably retained. In other words, even if the data in the flash memory 202 is corrupted, the read request from the host device 100 can be handled by the data in the HD 201.

A. Synchronization processing corresponding to the presence or absence of external power supply connection (1)
FIG. 3 is a flowchart showing an example of details of the writing process in step S14.
(1) Determination of whether write target data exists in the flash memory 202 (step S21)
It is determined whether data to be written exists in the flash memory 202 or not. When rewriting existing data, there is a possibility that the address of the data to be rewritten exists in the flash memory 202.

(2) Confirmation of free space in flash memory 202 (step S22)
When the data to be written does not exist in the flash memory 202 (when the existing data is not rewritten), it is confirmed whether or not there is a free area corresponding to the data to be written into the flash memory 202.

(3) Reserving an empty area in the flash memory 202 (steps S23 to S26)
When there is no free area corresponding to the data to be written to the flash memory 202, the free area is increased and data can be written to the flash memory 202 as follows.

  That is, the data in the flash memory 202 is searched. If the searched data exists in the HD 201, the data is deleted from the flash memory 202. If the retrieved data does not exist in the HD 201, the data is written in the HD 201 and erased from the flash memory 202.

  A cache table on the flash memory 202 can be used for these processes. That is, data retrieval on the flash memory 202, existence confirmation on the HD 201, and data erasure can all be performed on the cache table. Synchronization information can be used for presence confirmation in the HD 201. In addition, data is erased from the flash memory 202 by deleting cache information (entries) from the cache table. That is, if the entry on the cache table is deleted, the actual data on the write area need not be deleted.

(4) Confirmation of connection of external power supply (step S31)
Check if the external power supply is connected. That is, the detection result stored in the connection information storage unit 214 is referred to, and it is confirmed whether this detection result represents whether or not the external power source is connected.

(5) Write asynchronous data to HD 201 (step S32)
When an external power supply is connected, data (asynchronous data) that exists only in the flash memory 202 and does not exist in the HD 201 is written into the HD 201 (step S31). That is, data is synchronized between the flash memory 202 and the HD 201 (ensuring consistency). This step S32 can be executed by the above-described steps S23 to S25.

  At this time, all data in the flash memory 202 can exist in the HD 201 (100% synchronization). Alternatively, the synchronization may be stopped at a predetermined rate. Note that the cache table is updated as data is synchronized.

  Here, the data written to the HD 201 (synchronized data) may be deleted from the flash memory 202. In this case, many free areas are created in the flash memory 202 in response to the deletion of data from the flash memory 202. This deletion of data can be detected as a cache miss. For example, if a “Query NV Cache Misses” command is used, it is possible to detect the occurrence of a cache miss corresponding to the creation of a free area in the present embodiment. That is, the frequency of occurrence of cache misses changes depending on whether or not an external power supply is connected.

(6) Writing of write target data (step S33)
Data to be written is written to the flash memory 202 and the HD 201.
Here, both the flash memory 202 and the HD 201 or only the flash memory 202 may be selected as the write destination in accordance with whether or not the external power supply is connected. That is, when an external power supply is connected, data is written to both the flash memory 202 and the HD 201. When the external power supply is not connected, data is written only to the flash memory 202. Corresponding to whether or not an external power supply is connected, that is, whether or not the battery is driven, writing to the HD 201 can be omitted, and power consumption when the battery is driven can be reduced.

  As described above, by synchronizing the data in the flash memory 202 and the HD 201 (writing the data cached in the flash memory 202 to the HD 201), it is possible to save the data in the flash memory 202 and the HD 201 twice. is there. As a result, even if the data in the flash memory 202 is corrupted, the data can be recovered by referring to the data in the HD 201.

  The reason for synchronizing the data according to whether or not the external power supply is connected is as follows. In the present embodiment, the HD 201 is operated by a battery of the power source 220. For this reason, when an external power source is not connected to the power source 220, power consumption is reduced by restricting access to the HD 201. As a result, the driving time by the battery can be secured. On the other hand, when an external power source is connected to the power source 220, there is no need to worry about power consumption, and the necessity for restricting access to the HD 201 is reduced. In other words, the synchronization processing corresponding to the connection of the external power supply enables both low power consumption operation when the battery is operated and data safety when the external power supply is connected.

B. Synchronization processing corresponding to the presence or absence of external power supply connection (2)
FIG. 4 is a flowchart showing another example of details of the writing process in step S14. Steps S21 to S26 are the same as in FIG.

(1) Setting of synchronization start parameters (steps S41 to S43)
Set the synchronization start parameter according to whether the external power supply is connected. In this example, the reference value X of the ratio A of asynchronous data on the flash memory 202 is used as a synchronization start parameter, and the value is changed according to whether or not an external power supply is connected. Here, the reference value X of the ratio A is 5% when the external power supply is connected, and the reference value X of the ratio A is 50% when the external power supply is not connected. The ratio A of asynchronous data on the flash memory 202 can be calculated from the ratio of no synchronization in the synchronization information on the cache table.

  By reducing the ratio reference value X when an external power supply is connected, the possibility of starting data flash is increased. In the example of FIG. 3, the presence or absence of the data flash start is determined only by whether or not the external power supply is connected. On the other hand, the flexibility of the response is improved and the balance between low power consumption and data safety is improved. It is easier to secure.

  Note that the amount of asynchronous data may be used as the synchronization start parameter instead of the ratio of asynchronous data.

(2) Writing asynchronous data to the HD 201 (steps S44 to S46)
When the ratio A of asynchronous data on the flash memory 202 is equal to or greater than the reference value X (step S44), asynchronous data) is written to the HD 201 (step S45). That is, data is synchronized between the flash memory 202 and the HD 201 (ensuring consistency). This step S45 can be executed by the aforementioned steps S23 to S25.

  This writing is continued until the asynchronous data ratio A becomes smaller than the reference value X. That is, in the example of FIG. 3, when data synchronization is started, the processing becomes more flexible than when data is synchronized until 100% synchronization is completed. Alternatively, when data synchronization processing is started, data synchronization can be continued until 100% synchronization is achieved.

  Here, in the example of FIG. 4, data (synchronized data) written to the HD 201 is deleted from the flash memory 202. As described above, synchronized data is deleted by deleting cache information (entries) from the cache table. Instead of deleting the data, the synchronized data can be held in the flash memory 202 as it is (step S46 is omitted). By doing so, data is retained twice, and data retention is more reliable.

  Execution of data deletion can be detected as occurrence of a cache miss by using, for example, a “Query NV Cache Misses” command. The frequency of cache misses varies depending on whether external power is connected.

(3) Writing of write target data (step S47)
Data to be written is written to the flash memory 202 and the HD 201. Here, as described in step S33 of FIG. 3, both the flash memory 202 and the HD 201 or only the flash memory 202 may be selected as the write destination in accordance with the presence or absence of the connection of the external power supply.

C. Synchronization processing corresponding to the presence or absence of external power supply connection (3)
A. above. B. In this case, it is assumed that the write command is detected and the operation switch 232 is in the OFF state. That is, whether or not synchronization is started is determined at the time of detection of the write command. On the other hand, whether or not synchronization is started may be determined when an external power supply is connected, regardless of whether or not a write command is detected.

D. Synchronization processing corresponding to the operation switch 232 By setting the operation switch 232 to the ON state, the same processing as when the connection of the external power source is detected can be executed. For example, the synchronization of data between the flash memory 202 and the HD 201 can be started regardless of the detection of the write command and the presence or absence of connection of the external power supply. Specifically, when the operation switch 232 is turned on, the synchronization process shown in step S32 of FIG. 3 is executed. Here, the data written to the HD 201 (synchronized data) may be deleted from the flash memory 202 as necessary. Furthermore, steps S42 to S46 of FIG. 4 can be executed in the same manner as the connection of the external power supply is detected.

(Second Embodiment)
A second embodiment of the present invention will be described.
FIG. 5 is a block diagram showing an electronic device 300 according to the second embodiment of the present invention. The electronic device 300 includes a main processing unit 310, a hard disk (HD) 201, a flash memory 202, an SDRAM 203, a main controller 210, a power supply 220, a power supply controller 331, an operation switch 232, a status sensor 240, a host interface 251, a disk interface 252, and a flash. It has a memory interface 253, an SDRAM interface 254, a sensor interface 256, and a switch interface 257.

  The electronic device 300 can correspond to various devices such as an audio playback device (audio player), a video playback device, a game machine, a personal computer, and an electronic notebook. In the information recording system 10, the electronic device 300 is configured as an integrated device, whereas the information recording system 10 includes the host device 100 and the information recording device 200.

  The electronic device 300 includes a main processing unit 310 instead of the host device 100 in the information recording system 10. The main processing unit 310 exhibits basic functions (for example, an audio playback function, a video playback function, and a game function) of the electronic device 300.

In the electronic device 300, the power interface 255 does not exist, and the power controller 331 is connected to the main processing unit 310. That is, the detection result of the connection of the external power source in the power controller 331 is notified to the main controller 210 via the main processing unit 310. For this notification, a control signal and a command from the main processing unit 310 can be used. As a command, either a dedicated command or an unused part (argument part) of an existing command can be used. Further, the detection result may be notified to the main controller 210 using a physical switch instead of the control signal and the command.
As in the first embodiment, the detection result may be notified to the main controller 210 not via the main processor 310 but via the power interface.

  Since the operation procedure of the electronic device 300 is not essentially different from that of the information recording apparatus 200, description thereof is omitted.

(Other embodiments)
Embodiments of the present invention are not limited to the above-described embodiments, and can be expanded and modified. The expanded and modified embodiments are also included in the technical scope of the present invention.

1 is a block diagram illustrating an information recording system according to a first embodiment of the present invention. It is a flowchart showing an example of the operation | movement procedure of an information recording device. FIG. 3 is a flowchart showing an example of details of a writing process in step S14 of FIG. It is a flowchart showing another example of the detail of the write-in process in FIG.2 S14. It is a block diagram showing the electronic device which concerns on the 2nd Embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Information recording system, 100 ... Host apparatus, 200 ... Information recording apparatus, 201 ... Hard disk, 202 ... Flash memory, 203 ... SDRAM, 210 ... Main controller, 211 ... Command analysis part, 212 ... Access permission determination part, 213 ... Access enable / disable storage unit, 214 ... connection information storage unit, 215 ... operation information storage unit, 216 ... synchronization determination unit, 217 ... write / read unit, 220 ... power source, 231 ... power supply controller, 232 ... operation switch, 240 ... state Sensor, 251 ... Host interface, 252 ... Disk interface, 253 ... Flash memory interface, 254 ... SDRAM interface, 255 ... Power supply interface, 256 ... Sensor interface, 257 ... Switch interface, 300 ... Electronics , 310 ... main unit, 331 ... power supply controller

Claims (9)

An information recording device for writing data to a disk-shaped recording medium and a cache memory,
A storage unit for storing connection information indicating whether or not an external power supply is connected;
A determination unit for determining whether to write data recorded only in the cache memory to the disk-shaped recording medium based on the connection information;
In response to the determination result, a writing unit that writes data recorded only in the cache memory to the disk-shaped recording medium;
An information recording apparatus comprising: A power supply that stores and supplies power from an external power supply;
A detection unit for detecting connection of an external power source to the power source,
The information recording apparatus according to claim 1, wherein the connection information represents a detection result by the detection unit. The information recording apparatus according to claim 1, wherein the connection information represents whether or not an external power source is connected to a host apparatus connected to the information recording apparatus. An operation switch,
4. The determination unit according to claim 1, wherein the determination unit determines whether or not to write data recorded only in the cache memory to the disk-shaped recording medium based on an operation of the operation switch. The information recording apparatus according to item 1. A second storage unit for storing access permission information indicating permission or prohibition of access to the disk-shaped recording medium;
A second writing unit for writing data to either the disk-shaped recording medium and the cache memory or only the cache memory in response to the access permission information;
The information recording apparatus according to claim 1, further comprising: The information recording apparatus according to claim 1, further comprising a deletion unit that deletes data written on the disk-shaped recording medium by the writing unit from the cache memory. . The determination unit is
A first determination unit for determining a value based on the connection information;
Determine whether to write data recorded only in the cache memory to the disk-shaped recording medium based on a comparison result between the amount or ratio of data recorded only in the cache memory and the determined value A second decision unit to
The information recording apparatus according to claim 1, wherein the information recording apparatus is an information recording apparatus. A write detection unit for detecting a write command from a host device connected to the information recording device;
The information recording apparatus according to claim 1, wherein the determination unit determines whether or not to write in response to detection of the write command. An information recording method in an information recording device for writing data to a disk-shaped recording medium and a cache memory,
Writing data into either the disk-shaped recording medium and the cache memory or only the cache memory in response to access permission / inhibition information indicating permission or prohibition of access to the disk-shaped recording medium;
Determining whether to write data recorded only in the cache memory to the disk-shaped recording medium based on the presence or absence of a predetermined detection;
In response to the result of the determination, writing data recorded only in the cache memory to the disk-shaped recording medium;
An information recording method comprising:

Images